/*
   Copyright (c) 2017, MariaDB
   Copyright (C) 2014 InfiniDB, Inc.

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License
   as published by the Free Software Foundation; version 2 of
   the License.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
   MA 02110-1301, USA.
*/

//
// C++ Implementation: rowgroup
//
// Description:
//
// Author: Patrick LeBlanc <pleblanc@calpont.com>, (C) 2008
//

#include <vector>
//#define NDEBUG
#include <cassert>
#include <string>
#include <sstream>
#include <iterator>
using namespace std;

#include <boost/shared_array.hpp>
using namespace boost;

#include "bytestream.h"
using namespace messageqcpp;

#include "calpontsystemcatalog.h"
using namespace execplan;

#include "joblisttypes.h"
#include "nullvaluemanip.h"
#include "rowgroup.h"

namespace rowgroup
{

StringStore::StringStore() : empty(true), fUseStoreStringMutex(false) { }

StringStore::StringStore(const StringStore&)
{
    throw logic_error("Don't call StringStore copy ctor");
}

StringStore& StringStore::operator=(const StringStore&)
{
    throw logic_error("Don't call StringStore operator=");
}

StringStore::~StringStore()
{
#if 0
    // for mem usage debugging
    uint32_t i;
    uint64_t inUse = 0, allocated = 0;

    for (i = 0; i < mem.size(); i++)
    {
        MemChunk* tmp = (MemChunk*) mem.back().get();
        inUse += tmp->currentSize;
        allocated += tmp->capacity;
    }

    if (allocated > 0)
        cout << "~SS: " << inUse << "/" << allocated << " = " << (float) inUse / (float) allocated << endl;

#endif
}

uint64_t StringStore::storeString(const uint8_t* data, uint32_t len)
{
    MemChunk* lastMC = NULL;
    uint64_t ret = 0;

    empty = false;   // At least a NULL is being stored.

    // Sometimes the caller actually wants "" to be returned.......   argggghhhh......
    //if (len == 0)
    //	return numeric_limits<uint32_t>::max();

    if ((len == 8 || len == 9) &&
            *((uint64_t*) data) == *((uint64_t*) joblist::CPNULLSTRMARK.c_str()))
        return numeric_limits<uint64_t>::max();

    //@bug6065, make StringStore::storeString() thread safe
    boost::mutex::scoped_lock lk(fMutex, defer_lock);

    if (fUseStoreStringMutex)
        lk.lock();

    if (mem.size() > 0)
        lastMC = (MemChunk*) mem.back().get();

    if ((len + 4) >= CHUNK_SIZE)
    {
        shared_array<uint8_t> newOne(new uint8_t[len + sizeof(MemChunk) + 4]);
        longStrings.push_back(newOne);
        lastMC = (MemChunk*) longStrings.back().get();
        lastMC->capacity = lastMC->currentSize = len + 4;
        memcpy(lastMC->data, &len, 4);
        memcpy(lastMC->data + 4, data, len);
        // High bit to mark a long string
        ret = 0x8000000000000000;
        ret += longStrings.size() - 1;
    }
    else
    {
        if ((lastMC == NULL) || (lastMC->capacity - lastMC->currentSize < (len + 4)))
        {
            // mem usage debugging
            //if (lastMC)
            //cout << "Memchunk efficiency = " << lastMC->currentSize << "/" << lastMC->capacity << endl;
            shared_array<uint8_t> newOne(new uint8_t[CHUNK_SIZE + sizeof(MemChunk)]);
            mem.push_back(newOne);
            lastMC = (MemChunk*) mem.back().get();
            lastMC->currentSize = 0;
            lastMC->capacity = CHUNK_SIZE;
            memset(lastMC->data, 0, CHUNK_SIZE);
        }


        ret = ((mem.size() - 1) * CHUNK_SIZE) + lastMC->currentSize;

        // If this ever happens then we have big problems
        if (ret & 0x8000000000000000)
            throw logic_error("StringStore memory exceeded.");

        memcpy(&(lastMC->data[lastMC->currentSize]), &len, 4);
        memcpy(&(lastMC->data[lastMC->currentSize]) + 4, data, len);
        /*
        cout << "stored: '" << hex;
        for (uint32_t i = 0; i < len ; i++) {
                cout << (char) lastMC->data[lastMC->currentSize + i];
        }
        cout << "' at position " << lastMC->currentSize << " len " << len << dec << endl;
        */
        lastMC->currentSize += len + 4;
    }

    return ret;
}

void StringStore::serialize(ByteStream& bs) const
{
    uint64_t i;
    MemChunk* mc;

    bs << (uint64_t) mem.size();
    bs << (uint8_t) empty;

    for (i = 0; i < mem.size(); i++)
    {
        mc = (MemChunk*) mem[i].get();
        bs << (uint64_t) mc->currentSize;
        //cout << "serialized " << mc->currentSize << " bytes\n";
        bs.append(mc->data, mc->currentSize);
    }

    bs << (uint64_t) longStrings.size();

    for (i = 0; i < longStrings.size(); i++)
    {
        mc = (MemChunk*) longStrings[i].get();
        bs << (uint64_t) mc->currentSize;
        bs.append(mc->data, mc->currentSize);
    }
}

void StringStore::deserialize(ByteStream& bs)
{
    uint64_t i;
    uint64_t count;
    uint64_t size;
    uint8_t* buf;
    MemChunk* mc;
    uint8_t tmp8;

    //mem.clear();
    bs >> count;
    mem.resize(count);
    bs >> tmp8;
    empty = (bool) tmp8;

    for (i = 0; i < count; i++)
    {
        bs >> size;
        //cout << "deserializing " << size << " bytes\n";
        buf = bs.buf();
        mem[i].reset(new uint8_t[size + sizeof(MemChunk)]);
        mc = (MemChunk*) mem[i].get();
        mc->currentSize = size;
        mc->capacity = size;
        memcpy(mc->data, buf, size);
        bs.advance(size);
    }

    bs >> count;
    longStrings.resize(count);

    for (i = 0; i < count; i++)
    {
        bs >> size;
        buf = bs.buf();
        longStrings[i].reset(new uint8_t[size + sizeof(MemChunk)]);
        mc = (MemChunk*) longStrings[i].get();
        mc->capacity = mc->currentSize = size;
        memcpy(mc->data, buf, size);
        bs.advance(size);
    }

    return;
}

void StringStore::clear()
{
    vector<shared_array<uint8_t> > emptyv;
    vector<shared_array<uint8_t> > emptyv2;
    mem.swap(emptyv);
    longStrings.swap(emptyv2);
    empty = true;
}

UserDataStore::UserDataStore() : fUseUserDataMutex(false)
{
}

UserDataStore::~UserDataStore()
{
}

uint32_t UserDataStore::storeUserData(mcsv1sdk::mcsv1Context& context,
                                      boost::shared_ptr<mcsv1sdk::UserData> data,
                                      uint32_t len)
{
    uint32_t ret = 0;

    if (len == 0 || data == NULL)
    {
        return numeric_limits<uint32_t>::max();
    }

    boost::mutex::scoped_lock lk(fMutex, defer_lock);

    if (fUseUserDataMutex)
        lk.lock();

    StoreData storeData;
    storeData.length = len;
    storeData.functionName = context.getName();
    storeData.userData = data;
    vStoreData.push_back(storeData);

    ret = vStoreData.size();

    return ret;
}

boost::shared_ptr<mcsv1sdk::UserData> UserDataStore::getUserData(uint32_t off) const
{
    if (off == std::numeric_limits<uint32_t>::max())
        return  boost::shared_ptr<mcsv1sdk::UserData>();

    if ((vStoreData.size() < off) || off == 0)
        return  boost::shared_ptr<mcsv1sdk::UserData>();

    return vStoreData[off - 1].userData;
}


void UserDataStore::serialize(ByteStream& bs) const
{
    size_t i;

    bs << (uint32_t) vStoreData.size();

    for (i = 0; i < vStoreData.size(); ++i)
    {
        const StoreData& storeData = vStoreData[i];
        bs << storeData.length;
        bs << storeData.functionName;
        storeData.userData->serialize(bs);
    }
}

void UserDataStore::deserialize(ByteStream& bs)
{
    size_t i;
    uint32_t cnt;
    bs >> cnt;

//	vStoreData.clear();
    vStoreData.resize(cnt);

    for (i = 0; i < cnt; i++)
    {
        bs >> vStoreData[i].length;
        bs >> vStoreData[i].functionName;

        // We don't have easy access to the context here, so we do our own lookup
        if (vStoreData[i].functionName.length() == 0)
        {
            throw std::logic_error("UserDataStore::deserialize: has empty name");
        }

        mcsv1sdk::UDAF_MAP::iterator funcIter = mcsv1sdk::UDAFMap::getMap().find(vStoreData[i].functionName);

        if (funcIter == mcsv1sdk::UDAFMap::getMap().end())
        {
            std::ostringstream errmsg;
            errmsg << "UserDataStore::deserialize: " << vStoreData[i].functionName << " is undefined";
            throw std::logic_error(errmsg.str());
        }

        mcsv1sdk::mcsv1_UDAF::ReturnCode rc;
        mcsv1sdk::UserData* userData = NULL;
        rc = funcIter->second->createUserData(userData, vStoreData[i].length);

        if (rc != mcsv1sdk::mcsv1_UDAF::SUCCESS)
        {
            std::ostringstream errmsg;
            errmsg << "UserDataStore::deserialize: " << vStoreData[i].functionName << " createUserData failed(" << rc << ")";
            throw std::logic_error(errmsg.str());
        }

        userData->unserialize(bs);
        vStoreData[i].userData = boost::shared_ptr<mcsv1sdk::UserData>(userData);
    }

    return;
}

//uint32_t rgDataCount = 0;

RGData::RGData()
{
    //cout << "rgdata++ = " << __sync_add_and_fetch(&rgDataCount, 1) << endl;
}

RGData::RGData(const RowGroup& rg, uint32_t rowCount)
{
    //cout << "rgdata++ = " << __sync_add_and_fetch(&rgDataCount, 1) << endl;
    rowData.reset(new uint8_t[rg.getDataSize(rowCount)]);

    if (rg.usesStringTable() && rowCount > 0)
        strings.reset(new StringStore());

#ifdef VALGRIND
    /* In a PM-join, we can serialize entire tables; not every value has been
     * filled in yet.  Need to look into that.  Valgrind complains that
     * those bytes are uninitialized, this suppresses that error.
     */
    memset(rowData.get(), 0, rg.getDataSize(rowCount));   // XXXPAT: make valgrind happy temporarily
#endif
}

RGData::RGData(const RowGroup& rg)
{
    //cout << "rgdata++ = " << __sync_add_and_fetch(&rgDataCount, 1) << endl;
    rowData.reset(new uint8_t[rg.getMaxDataSize()]);

    if (rg.usesStringTable())
        strings.reset(new StringStore());

#ifdef VALGRIND
    /* In a PM-join, we can serialize entire tables; not every value has been
     * filled in yet.  Need to look into that.  Valgrind complains that
     * those bytes are uninitialized, this suppresses that error.
     */
    memset(rowData.get(), 0, rg.getMaxDataSize());
#endif
}

void RGData::reinit(const RowGroup& rg, uint32_t rowCount)
{
    rowData.reset(new uint8_t[rg.getDataSize(rowCount)]);

    if (rg.usesStringTable())
        strings.reset(new StringStore());
    else
        strings.reset();

#ifdef VALGRIND
    /* In a PM-join, we can serialize entire tables; not every value has been
     * filled in yet.  Need to look into that.  Valgrind complains that
     * those bytes are uninitialized, this suppresses that error.
     */
    memset(rowData.get(), 0, rg.getDataSize(rowCount));
#endif
}

void RGData::reinit(const RowGroup& rg)
{
    reinit(rg, 8192);
}

RGData::RGData(const RGData& r) : rowData(r.rowData), strings(r.strings), userDataStore(r.userDataStore)
{
    //cout << "rgdata++ = " << __sync_add_and_fetch(&rgDataCount, 1) << endl;
}

RGData::~RGData()
{
    //cout << "rgdata-- = " << __sync_sub_and_fetch(&rgDataCount, 1) << endl;
}

void RGData::serialize(ByteStream& bs, uint32_t amount) const
{
    //cout << "serializing!\n";
    bs << (uint32_t) RGDATA_SIG;
    bs << (uint32_t) amount;
    bs.append(rowData.get(), amount);

    if (strings)
    {
        bs << (uint8_t) 1;
        strings->serialize(bs);
    }
    else
        bs << (uint8_t) 0;

    if (userDataStore)
    {
        bs << (uint8_t) 1;
        userDataStore->serialize(bs);
    }
    else
        bs << (uint8_t) 0;
}

void RGData::deserialize(ByteStream& bs, bool hasLenField)
{
    uint32_t amount, sig;
    uint8_t* buf;
    uint8_t tmp8;

    bs.peek(sig);

    if (sig == RGDATA_SIG)
    {
        bs >> sig;
        bs >> amount;
        rowData.reset(new uint8_t[amount]);
        buf = bs.buf();
        memcpy(rowData.get(), buf, amount);
        bs.advance(amount);
        bs >> tmp8;

        if (tmp8)
        {
            strings.reset(new StringStore());
            strings->deserialize(bs);
        }
        else
            strings.reset();

        // UDAF user data
        bs >> tmp8;

        if (tmp8)
        {
            userDataStore.reset(new UserDataStore());
            userDataStore->deserialize(bs);
        }
        else
            userDataStore.reset();
    }

    return;
}

void RGData::clear()
{
    rowData.reset();
    strings.reset();
}

// UserDataStore is only used for UDAF.
// Just in time construction because most of the time we don't need one.
UserDataStore* RGData::getUserDataStore()
{
    if (!userDataStore)
    {
        userDataStore.reset(new UserDataStore);
    }

    return userDataStore.get();
}

Row::Row() : data(NULL), strings(NULL), userDataStore(NULL) { }

Row::Row(const Row& r) : columnCount(r.columnCount), baseRid(r.baseRid),
    oldOffsets(r.oldOffsets), stOffsets(r.stOffsets),
    offsets(r.offsets), colWidths(r.colWidths), types(r.types), data(r.data),
    scale(r.scale), precision(r.precision), strings(r.strings),
    useStringTable(r.useStringTable), hasLongStringField(r.hasLongStringField),
    sTableThreshold(r.sTableThreshold), forceInline(r.forceInline), userDataStore(NULL)
{ }

Row::~Row() { }

Row& Row::operator=(const Row& r)
{
    columnCount = r.columnCount;
    baseRid = r.baseRid;
    oldOffsets = r.oldOffsets;
    stOffsets = r.stOffsets;
    offsets = r.offsets;
    colWidths = r.colWidths;
    types = r.types;
    data = r.data;
    scale = r.scale;
    precision = r.precision;
    strings = r.strings;
    useStringTable = r.useStringTable;
    hasLongStringField = r.hasLongStringField;
    sTableThreshold = r.sTableThreshold;
    forceInline = r.forceInline;
    return *this;
}

string Row::toString() const
{
    ostringstream os;
    uint32_t i;

    //os << getRid() << ": ";
    os << (int) useStringTable << ": ";

    for (i = 0; i < columnCount; i++)
    {
        if (isNullValue(i))
            os << "NULL ";
        else
            switch (types[i])
            {
                case CalpontSystemCatalog::CHAR:
                case CalpontSystemCatalog::VARCHAR:
                {
                    const string& tmp = getStringField(i);
                    os << "(" << getStringLength(i) << ") '" << tmp << "' ";
                    break;
                }

                case CalpontSystemCatalog::FLOAT:
                case CalpontSystemCatalog::UFLOAT:
                    os << getFloatField(i) << " ";
                    break;

                case CalpontSystemCatalog::DOUBLE:
                case CalpontSystemCatalog::UDOUBLE:
                    os << getDoubleField(i) << " ";
                    break;

                case CalpontSystemCatalog::LONGDOUBLE:
                    os << getLongDoubleField(i) << " ";
                    break;

                case CalpontSystemCatalog::VARBINARY:
                case CalpontSystemCatalog::BLOB:
                case CalpontSystemCatalog::TEXT:
                {
                    uint32_t len = getVarBinaryLength(i);
                    const uint8_t* val = getVarBinaryField(i);
                    os << "0x" << hex;

                    while (len-- > 0)
                    {
                        os << (uint32_t)(*val >> 4);
                        os << (uint32_t)(*val++ & 0x0F);
                    }

                    os << " " << dec;
                    break;
                }

                default:
                    os << getIntField(i) << " ";
                    break;
            }
    }

    return os.str();
}

string Row::toCSV() const
{
    ostringstream os;

    for (uint32_t i = 0; i < columnCount; i++)
    {
        if (i > 0)
        {
            os << ",";
        }

        if (isNullValue(i))
            os << "NULL";
        else
            switch (types[i])
            {
                case CalpontSystemCatalog::CHAR:
                case CalpontSystemCatalog::VARCHAR:
                    os << getStringField(i).c_str();
                    break;

                case CalpontSystemCatalog::FLOAT:
                case CalpontSystemCatalog::UFLOAT:
                    os << getFloatField(i);
                    break;

                case CalpontSystemCatalog::DOUBLE:
                case CalpontSystemCatalog::UDOUBLE:
                    os << getDoubleField(i);
                    break;

                case CalpontSystemCatalog::LONGDOUBLE:
                    os << getLongDoubleField(i);
                    break;

                case CalpontSystemCatalog::VARBINARY:
                case CalpontSystemCatalog::BLOB:
                case CalpontSystemCatalog::TEXT:
                {
                    uint32_t len = getVarBinaryLength(i);
                    const uint8_t* val = getVarBinaryField(i);
                    os << "0x" << hex;

                    while (len-- > 0)
                    {
                        os << (uint32_t)(*val >> 4);
                        os << (uint32_t)(*val++ & 0x0F);
                    }

                    os << dec;
                    break;
                }

                default:
                    os << getIntField(i);
                    break;
            }
    }

    return os.str();
}

void Row::initToNull()
{
    uint32_t i;

    for (i = 0; i < columnCount; i++)
    {
        switch (types[i])
        {
            case CalpontSystemCatalog::TINYINT:
                data[offsets[i]] = joblist::TINYINTNULL;
                break;

            case CalpontSystemCatalog::SMALLINT:
                *((int16_t*) &data[offsets[i]]) = static_cast<int16_t>(joblist::SMALLINTNULL);
                break;

            case CalpontSystemCatalog::MEDINT:
            case CalpontSystemCatalog::INT:
                *((int32_t*) &data[offsets[i]]) = static_cast<int32_t>(joblist::INTNULL);
                break;

            case CalpontSystemCatalog::FLOAT:
            case CalpontSystemCatalog::UFLOAT:
                *((int32_t*) &data[offsets[i]]) = static_cast<int32_t>(joblist::FLOATNULL);
                break;

            case CalpontSystemCatalog::DATE:
                *((int32_t*) &data[offsets[i]]) = static_cast<int32_t>(joblist::DATENULL);
                break;

            case CalpontSystemCatalog::BIGINT:
                if (precision[i] != 9999)
                    *((uint64_t*) &data[offsets[i]]) = joblist::BIGINTNULL;
                else  // work around for count() in outer join result.
                    *((uint64_t*) &data[offsets[i]]) = 0;

                break;

            case CalpontSystemCatalog::DOUBLE:
            case CalpontSystemCatalog::UDOUBLE:
                *((uint64_t*) &data[offsets[i]]) = joblist::DOUBLENULL;
                break;

            case CalpontSystemCatalog::DATETIME:
                *((uint64_t*) &data[offsets[i]]) = joblist::DATETIMENULL;
                break;

            case CalpontSystemCatalog::TIME:
                *((uint64_t*) &data[offsets[i]]) = joblist::TIMENULL;
                break;

            case CalpontSystemCatalog::CHAR:
            case CalpontSystemCatalog::VARCHAR:
            case CalpontSystemCatalog::TEXT:
            case CalpontSystemCatalog::STRINT:
            {
                if (inStringTable(i))
                {
                    setStringField(joblist::CPNULLSTRMARK, i);
                    break;
                }

                uint32_t len = getColumnWidth(i);

                switch (len)
                {
                    case 1:
                        data[offsets[i]] = joblist::CHAR1NULL;
                        break;

                    case 2:
                        *((uint16_t*) &data[offsets[i]]) = joblist::CHAR2NULL;
                        break;

                    case 3:
                    case 4:
                        *((uint32_t*) &data[offsets[i]]) = joblist::CHAR4NULL;
                        break;

                    case 5:
                    case 6:
                    case 7:
                    case 8:
                        *((uint64_t*) &data[offsets[i]]) = joblist::CHAR8NULL;
                        break;

                    default:
                        *((uint64_t*) &data[offsets[i]]) = *((uint64_t*) joblist::CPNULLSTRMARK.c_str());
                        memset(&data[offsets[i] + 8], 0, len - 8);
                        //strcpy((char *) &data[offsets[i]], joblist::CPNULLSTRMARK.c_str());
                        break;
                }

                break;
            }

            case CalpontSystemCatalog::VARBINARY:
            case CalpontSystemCatalog::BLOB:
                *((uint16_t*) &data[offsets[i]]) = 0;
                break;

            case CalpontSystemCatalog::DECIMAL:
            case CalpontSystemCatalog::UDECIMAL:
            {
                uint32_t len = getColumnWidth(i);

                switch (len)
                {
                    case 1 :
                        data[offsets[i]] = joblist::TINYINTNULL;
                        break;

                    case 2 :
                        *((int16_t*) &data[offsets[i]]) = static_cast<int16_t>(joblist::SMALLINTNULL);
                        break;

                    case 4 :
                        *((int32_t*) &data[offsets[i]]) = static_cast<int32_t>(joblist::INTNULL);
                        break;

                    default:
                        *((int64_t*) &data[offsets[i]]) = static_cast<int64_t>(joblist::BIGINTNULL);
                        break;
                }

                break;
            }

            case CalpontSystemCatalog::UTINYINT:
                data[offsets[i]] = joblist::UTINYINTNULL;
                break;

            case CalpontSystemCatalog::USMALLINT:
                *((uint16_t*) &data[offsets[i]]) = joblist::USMALLINTNULL;
                break;

            case CalpontSystemCatalog::UMEDINT:
            case CalpontSystemCatalog::UINT:
                *((uint32_t*) &data[offsets[i]]) = joblist::UINTNULL;
                break;

            case CalpontSystemCatalog::UBIGINT:
                *((uint64_t*) &data[offsets[i]]) = joblist::UBIGINTNULL;
                break;

            case CalpontSystemCatalog::LONGDOUBLE:
            {
                // no NULL value for long double yet, this is a nan.
                memset(&data[offsets[i]], 0xFF, getColumnWidth(i));
                break;
            }

            default:
                ostringstream os;
                os << "Row::initToNull(): got bad column type (" << types[i] <<
                   ").  Width=" << getColumnWidth(i) << endl;
                os << toString();
                throw logic_error(os.str());
        }
    }
}

bool Row::isNullValue(uint32_t colIndex) const
{
    switch (types[colIndex])
    {
        case CalpontSystemCatalog::TINYINT:
            return (data[offsets[colIndex]] == joblist::TINYINTNULL);

        case CalpontSystemCatalog::SMALLINT:
            return (*((int16_t*) &data[offsets[colIndex]]) == static_cast<int16_t>(joblist::SMALLINTNULL));

        case CalpontSystemCatalog::MEDINT:
        case CalpontSystemCatalog::INT:
            return (*((int32_t*) &data[offsets[colIndex]]) == static_cast<int32_t>(joblist::INTNULL));

        case CalpontSystemCatalog::FLOAT:
        case CalpontSystemCatalog::UFLOAT:
            return (*((int32_t*) &data[offsets[colIndex]]) == static_cast<int32_t>(joblist::FLOATNULL));

        case CalpontSystemCatalog::DATE:
            return (*((int32_t*) &data[offsets[colIndex]]) == static_cast<int32_t>(joblist::DATENULL));

        case CalpontSystemCatalog::BIGINT:
            return (*((int64_t*) &data[offsets[colIndex]]) == static_cast<int64_t>(joblist::BIGINTNULL));

        case CalpontSystemCatalog::DOUBLE:
        case CalpontSystemCatalog::UDOUBLE:
            return (*((uint64_t*) &data[offsets[colIndex]]) == joblist::DOUBLENULL);

        case CalpontSystemCatalog::DATETIME:
            return (*((uint64_t*) &data[offsets[colIndex]]) == joblist::DATETIMENULL);

        case CalpontSystemCatalog::TIME:
            return (*((uint64_t*) &data[offsets[colIndex]]) == joblist::TIMENULL);

        case CalpontSystemCatalog::CHAR:
        case CalpontSystemCatalog::VARCHAR:
        case CalpontSystemCatalog::STRINT:
        {
            uint32_t len = getColumnWidth(colIndex);

            if (inStringTable(colIndex))
            {
                uint64_t offset;
                offset = *((uint64_t*) &data[offsets[colIndex]]);
                return strings->isNullValue(offset);
            }

            if (data[offsets[colIndex]] == 0)   // empty string
                return true;

            switch (len)
            {
                case 1:
                    return (data[offsets[colIndex]] == joblist::CHAR1NULL);

                case 2:
                    return (*((uint16_t*) &data[offsets[colIndex]]) == joblist::CHAR2NULL);

                case 3:
                case 4:
                    return (*((uint32_t*) &data[offsets[colIndex]]) == joblist::CHAR4NULL);

                case 5:
                case 6:
                case 7:
                case 8:
                    return
                        (*((uint64_t*) &data[offsets[colIndex]]) == joblist::CHAR8NULL);

                default:
                    return (*((uint64_t*) &data[offsets[colIndex]]) == *((uint64_t*) joblist::CPNULLSTRMARK.c_str()));
            }

            break;
        }

        case CalpontSystemCatalog::DECIMAL:
        case CalpontSystemCatalog::UDECIMAL:
        {
            uint32_t len = getColumnWidth(colIndex);

            switch (len)
            {
                case 1 :
                    return (data[offsets[colIndex]] == joblist::TINYINTNULL);

                case 2 :
                    return (*((int16_t*) &data[offsets[colIndex]]) == static_cast<int16_t>(joblist::SMALLINTNULL));

                case 4 :
                    return (*((int32_t*) &data[offsets[colIndex]]) == static_cast<int32_t>(joblist::INTNULL));

                default:
                    return (*((int64_t*) &data[offsets[colIndex]]) == static_cast<int64_t>(joblist::BIGINTNULL));
            }

            break;
        }

        case CalpontSystemCatalog::BLOB:
        case CalpontSystemCatalog::TEXT:
        case CalpontSystemCatalog::VARBINARY:
        {
            uint32_t pos = offsets[colIndex];

            if (inStringTable(colIndex))
            {
                uint64_t offset;
                offset = *((uint64_t*) &data[pos]);
                return strings->isNullValue(offset);
            }

            if (*((uint16_t*) &data[pos]) == 0)
                return true;
            else if ((strncmp((char*) &data[pos + 2], joblist::CPNULLSTRMARK.c_str(), 8) == 0) &&
                     *((uint16_t*) &data[pos]) == joblist::CPNULLSTRMARK.length())
                return true;

            break;
        }

        case CalpontSystemCatalog::UTINYINT:
            return (data[offsets[colIndex]] == joblist::UTINYINTNULL);

        case CalpontSystemCatalog::USMALLINT:
            return (*((uint16_t*) &data[offsets[colIndex]]) == joblist::USMALLINTNULL);

        case CalpontSystemCatalog::UMEDINT:
        case CalpontSystemCatalog::UINT:
            return (*((uint32_t*) &data[offsets[colIndex]]) == joblist::UINTNULL);

        case CalpontSystemCatalog::UBIGINT:
            return (*((uint64_t*) &data[offsets[colIndex]]) == joblist::UBIGINTNULL);

        case CalpontSystemCatalog::LONGDOUBLE:
            // return false;  // no NULL value for long double yet
            break;

        default:
        {
            ostringstream os;
            os << "Row::isNullValue(): got bad column type (";
            os << types[colIndex];
            os << ").  Width=";
            os << getColumnWidth(colIndex) << endl;
            throw logic_error(os.str());
        }
    }

    return false;
}

uint64_t Row::getNullValue(uint32_t colIndex) const
{
    return utils::getNullValue(types[colIndex], getColumnWidth(colIndex));
#if 0

    switch (types[colIndex])
    {
        case CalpontSystemCatalog::TINYINT:
            return joblist::TINYINTNULL;

        case CalpontSystemCatalog::SMALLINT:
            return joblist::SMALLINTNULL;

        case CalpontSystemCatalog::MEDINT:
        case CalpontSystemCatalog::INT:
            return joblist::INTNULL;

        case CalpontSystemCatalog::FLOAT:
        case CalpontSystemCatalog::UFLOAT:
            return joblist::FLOATNULL;

        case CalpontSystemCatalog::DATE:
            return joblist::DATENULL;

        case CalpontSystemCatalog::BIGINT:
            return joblist::BIGINTNULL;

        case CalpontSystemCatalog::DOUBLE:
        case CalpontSystemCatalog::UDOUBLE:
            return joblist::DOUBLENULL;

        case CalpontSystemCatalog::DATETIME:
            return joblist::DATETIMENULL;

        case CalpontSystemCatalog::CHAR:
        case CalpontSystemCatalog::VARCHAR:
        case CalpontSystemCatalog::STRINT:
        {
            uint32_t len = getColumnWidth(colIndex);

            switch (len)
            {
                case 1:
                    return joblist::CHAR1NULL;

                case 2:
                    return joblist::CHAR2NULL;

                case 3:
                case 4:
                    return joblist::CHAR4NULL;

                case 5:
                case 6:
                case 7:
                case 8:
                    return joblist::CHAR8NULL;

                default:
                    throw logic_error("Row::getNullValue() Can't return the NULL string");
            }

            break;
        }

        case CalpontSystemCatalog::DECIMAL:
        case CalpontSystemCatalog::UDECIMAL:
        {
            uint32_t len = getColumnWidth(colIndex);

            switch (len)
            {
                case 1 :
                    return joblist::TINYINTNULL;

                case 2 :
                    return joblist::SMALLINTNULL;

                case 4 :
                    return joblist::INTNULL;

                default:
                    return joblist::BIGINTNULL;
            }

            break;
        }

        case CalpontSystemCatalog::UTINYINT:
            return joblist::UTINYINTNULL;

        case CalpontSystemCatalog::USMALLINT:
            return joblist::USMALLINTNULL;

        case CalpontSystemCatalog::UMEDINT:
        case CalpontSystemCatalog::UINT:
            return joblist::UINTNULL;

        case CalpontSystemCatalog::UBIGINT:
            return joblist::UBIGINTNULL;

        case CalpontSystemCatalog::LONGDOUBLE:
            return -1;  // no NULL value for long double yet, this is a nan.

        case CalpontSystemCatalog::VARBINARY:
        default:
            ostringstream os;
            os << "Row::getNullValue(): got bad column type (" << types[colIndex] <<
               ").  Width=" << getColumnWidth(colIndex) << endl;
            os << toString() << endl;
            throw logic_error(os.str());
    }

#endif
}

/* This fcn might produce overflow warnings from the compiler, but that's OK.
 * The overflow is intentional...
 */
int64_t Row::getSignedNullValue(uint32_t colIndex) const
{
    return utils::getSignedNullValue(types[colIndex], getColumnWidth(colIndex));
#if 0

    switch (types[colIndex])
    {
        case CalpontSystemCatalog::TINYINT:
            return (int64_t) ((int8_t) joblist::TINYINTNULL);

        case CalpontSystemCatalog::SMALLINT:
            return (int64_t) ((int16_t) joblist::SMALLINTNULL);

        case CalpontSystemCatalog::MEDINT:
        case CalpontSystemCatalog::INT:
            return (int64_t) ((int32_t) joblist::INTNULL);

        case CalpontSystemCatalog::FLOAT:
        case CalpontSystemCatalog::UFLOAT:
            return (int64_t) ((int32_t) joblist::FLOATNULL);

        case CalpontSystemCatalog::DATE:
            return (int64_t) ((int32_t) joblist::DATENULL);

        case CalpontSystemCatalog::BIGINT:
            return joblist::BIGINTNULL;

        case CalpontSystemCatalog::DOUBLE:
        case CalpontSystemCatalog::UDOUBLE:
            return joblist::DOUBLENULL;

        case CalpontSystemCatalog::DATETIME:
            return joblist::DATETIMENULL;

        case CalpontSystemCatalog::CHAR:
        case CalpontSystemCatalog::VARCHAR:
        case CalpontSystemCatalog::STRINT:
        {
            uint32_t len = getColumnWidth(colIndex);

            switch (len)
            {
                case 1:
                    return (int64_t) ((int8_t) joblist::CHAR1NULL);

                case 2:
                    return (int64_t) ((int16_t) joblist::CHAR2NULL);

                case 3:
                case 4:
                    return (int64_t) ((int32_t) joblist::CHAR4NULL);

                case 5:
                case 6:
                case 7:
                case 8:
                    return joblist::CHAR8NULL;

                default:
                    throw logic_error("Row::getSignedNullValue() Can't return the NULL string");
            }

            break;
        }

        case CalpontSystemCatalog::DECIMAL:
        case CalpontSystemCatalog::UDECIMAL:
        {
            uint32_t len = getColumnWidth(colIndex);

            switch (len)
            {
                case 1 :
                    return (int64_t) ((int8_t)  joblist::TINYINTNULL);

                case 2 :
                    return (int64_t) ((int16_t) joblist::SMALLINTNULL);

                case 4 :
                    return (int64_t) ((int32_t) joblist::INTNULL);

                default:
                    return joblist::BIGINTNULL;
            }

            break;
        }

        case CalpontSystemCatalog::UTINYINT:
            return (int64_t) ((int8_t) joblist::UTINYINTNULL);

        case CalpontSystemCatalog::USMALLINT:
            return (int64_t) ((int16_t) joblist::USMALLINTNULL);

        case CalpontSystemCatalog::UMEDINT:
        case CalpontSystemCatalog::UINT:
            return (int64_t) ((int32_t) joblist::UINTNULL);

        case CalpontSystemCatalog::UBIGINT:
            return (int64_t)joblist::UBIGINTNULL;

        case CalpontSystemCatalog::LONGDOUBLE:
            return -1;  // no NULL value for long double yet, this is a nan.

        case CalpontSystemCatalog::VARBINARY:
        default:
            ostringstream os;
            os << "Row::getSignedNullValue(): got bad column type (" << types[colIndex] <<
               ").  Width=" << getColumnWidth(colIndex) << endl;
            os << toString() << endl;
            throw logic_error(os.str());
    }

#endif
}

RowGroup::RowGroup() : columnCount(0), data(NULL), rgData(NULL), strings(NULL),
    useStringTable(true), hasLongStringField(false), sTableThreshold(20)
{
    oldOffsets.reserve(1024);
    oids.reserve(1024);
    keys.reserve(1024);
    types.reserve(1024);
    scale.reserve(1024);
    precision.reserve(1024);
}

RowGroup::RowGroup(uint32_t colCount,
                   const vector<uint32_t>& positions,
                   const vector<uint32_t>& roids,
                   const vector<uint32_t>& tkeys,
                   const vector<CalpontSystemCatalog::ColDataType>& colTypes,
                   const vector<uint32_t>& cscale,
                   const vector<uint32_t>& cprecision,
                   uint32_t stringTableThreshold,
                   bool stringTable,
                   const vector<bool>& forceInlineData
                  ) :
    columnCount(colCount), data(NULL), oldOffsets(positions), oids(roids), keys(tkeys),
    types(colTypes), scale(cscale), precision(cprecision), rgData(NULL), strings(NULL),
    sTableThreshold(stringTableThreshold)
{
    uint32_t i;

    forceInline.reset(new bool[columnCount]);

    if (forceInlineData.empty())
        for (i = 0; i < columnCount; i++)
            forceInline[i] = false;
    else
        for (i = 0; i < columnCount; i++)
            forceInline[i] = forceInlineData[i];

    colWidths.resize(columnCount);
    stOffsets.resize(columnCount + 1);
    stOffsets[0] = 2;  // 2-byte rid
    hasLongStringField = false;

    for (i = 0; i < columnCount; i++)
    {
        colWidths[i] = positions[i + 1] - positions[i];

        if (colWidths[i] >= sTableThreshold && !forceInline[i])
        {
            hasLongStringField = true;
            stOffsets[i + 1] = stOffsets[i] + 8;
        }
        else
            stOffsets[i + 1] = stOffsets[i] + colWidths[i];
    }

    useStringTable = (stringTable && hasLongStringField);
    offsets = (useStringTable ? &stOffsets[0] : &oldOffsets[0]);
}

RowGroup::RowGroup(const RowGroup& r) :
    columnCount(r.columnCount), data(r.data), oldOffsets(r.oldOffsets),
    stOffsets(r.stOffsets), colWidths(r.colWidths),
    oids(r.oids), keys(r.keys), types(r.types), scale(r.scale), precision(r.precision),
    rgData(r.rgData), strings(r.strings), useStringTable(r.useStringTable),
    hasLongStringField(r.hasLongStringField), sTableThreshold(r.sTableThreshold),
    forceInline(r.forceInline)
{
    //stOffsets and oldOffsets are sometimes empty...
    //offsets = (useStringTable ? &stOffsets[0] : &oldOffsets[0]);
    offsets = 0;

    if (useStringTable && !stOffsets.empty())
        offsets = &stOffsets[0];
    else if (!useStringTable && !oldOffsets.empty())
        offsets = &oldOffsets[0];
}

RowGroup& RowGroup::operator=(const RowGroup& r)
{
    columnCount = r.columnCount;
    oldOffsets = r.oldOffsets;
    stOffsets = r.stOffsets;
    colWidths = r.colWidths;
    oids = r.oids;
    keys = r.keys;
    types = r.types;
    data = r.data;
    scale = r.scale;
    precision = r.precision;
    rgData = r.rgData;
    strings = r.strings;
    useStringTable = r.useStringTable;
    hasLongStringField = r.hasLongStringField;
    sTableThreshold = r.sTableThreshold;
    forceInline = r.forceInline;
    //offsets = (useStringTable ? &stOffsets[0] : &oldOffsets[0]);
    offsets = 0;

    if (useStringTable && !stOffsets.empty())
        offsets = &stOffsets[0];
    else if (!useStringTable && !oldOffsets.empty())
        offsets = &oldOffsets[0];

    return *this;
}

RowGroup::~RowGroup()
{
}

void RowGroup::resetRowGroup(uint64_t rid)
{
    *((uint32_t*) &data[rowCountOffset]) = 0;
    *((uint64_t*) &data[baseRidOffset]) = rid;
    *((uint16_t*) &data[statusOffset]) = 0;
    *((uint32_t*) &data[dbRootOffset]) = 0;

    if (strings)
        strings->clear();
}

void RowGroup::serialize(ByteStream& bs) const
{
    bs << columnCount;
    serializeInlineVector<uint32_t>(bs, oldOffsets);
    serializeInlineVector<uint32_t>(bs, stOffsets);
    serializeInlineVector<uint32_t>(bs, colWidths);
    serializeInlineVector<uint32_t>(bs, oids);
    serializeInlineVector<uint32_t>(bs, keys);
    serializeInlineVector<CalpontSystemCatalog::ColDataType>(bs, types);
    serializeInlineVector<uint32_t>(bs, scale);
    serializeInlineVector<uint32_t>(bs, precision);
    bs << (uint8_t) useStringTable;
    bs << (uint8_t) hasLongStringField;
    bs << sTableThreshold;
    bs.append((uint8_t*) &forceInline[0], sizeof(bool) * columnCount);
}

void RowGroup::deserialize(ByteStream& bs)
{
    uint8_t tmp8;

    bs >> columnCount;
    deserializeInlineVector<uint32_t>(bs, oldOffsets);
    deserializeInlineVector<uint32_t>(bs, stOffsets);
    deserializeInlineVector<uint32_t>(bs, colWidths);
    deserializeInlineVector<uint32_t>(bs, oids);
    deserializeInlineVector<uint32_t>(bs, keys);
    deserializeInlineVector<CalpontSystemCatalog::ColDataType>(bs, types);
    deserializeInlineVector<uint32_t>(bs, scale);
    deserializeInlineVector<uint32_t>(bs, precision);
    bs >> tmp8;
    useStringTable = (bool) tmp8;
    bs >> tmp8;
    hasLongStringField = (bool) tmp8;
    bs >> sTableThreshold;
    forceInline.reset(new bool[columnCount]);
    memcpy(&forceInline[0], bs.buf(), sizeof(bool) * columnCount);
    bs.advance(sizeof(bool) * columnCount);
    //offsets = (useStringTable ? &stOffsets[0] : &oldOffsets[0]);
    offsets = 0;

    if (useStringTable && !stOffsets.empty())
        offsets = &stOffsets[0];
    else if (!useStringTable && !oldOffsets.empty())
        offsets = &oldOffsets[0];
}

void RowGroup::serializeRGData(ByteStream& bs) const
{
    //cout << "****** serializing\n" << toString() << en
//	if (useStringTable || !hasLongStringField)
    rgData->serialize(bs, getDataSize());
//	else {
//		uint64_t size;
//		RGData *compressed = convertToStringTable(&size);
//		compressed->serialize(bs, size);
//		if (compressed != rgData)
//			delete compressed;
//	}
}

uint32_t RowGroup::getDataSize() const
{
    return headerSize + (getRowCount() * offsets[columnCount]);
}

uint32_t RowGroup::getDataSize(uint64_t n) const
{
    return headerSize + (n * offsets[columnCount]);
}

uint32_t RowGroup::getMaxDataSize() const
{
    return headerSize + (8192 * offsets[columnCount]);
}

uint32_t RowGroup::getMaxDataSizeWithStrings() const
{
    return headerSize + (8192 * oldOffsets[columnCount]);
}

uint32_t RowGroup::getEmptySize() const
{
    return headerSize;
}

uint32_t RowGroup::getStatus() const
{
    return *((uint16_t*) &data[statusOffset]);
}

void RowGroup::setStatus(uint16_t err)
{
    *((uint16_t*) &data[statusOffset]) = err;
}

uint32_t RowGroup::getColumnWidth(uint32_t col) const
{
    return colWidths[col];
}

uint32_t RowGroup::getColumnCount() const
{
    return columnCount;
}

string RowGroup::toString() const
{
    ostringstream os;
    ostream_iterator<int> oIter1(os, "\t");

    os << "columncount = " << columnCount << endl;
    os << "oids:\t\t";
    copy(oids.begin(), oids.end(), oIter1);
    os << endl;
    os << "keys:\t\t";
    copy(keys.begin(), keys.end(), oIter1);
    os << endl;
    os << "offsets:\t";
    copy(&offsets[0], &offsets[columnCount + 1], oIter1);
    os << endl;
    os << "colWidths:\t";
    copy(colWidths.begin(), colWidths.end(), oIter1);
    os << endl;
    os << "types:\t\t";
    copy(types.begin(), types.end(), oIter1);
    os << endl;
    os << "scales:\t\t";
    copy(scale.begin(), scale.end(), oIter1);
    os << endl;
    os << "precisions:\t";
    copy(precision.begin(), precision.end(), oIter1);
    os << endl;

    if (useStringTable)
        os << "uses a string table\n";
    else
        os << "doesn't use a string table\n";

    //os << "strings = " << hex << (int64_t) strings << "\n";
    //os << "data = " << (int64_t) data << "\n" << dec;
    if (data != NULL)
    {
        Row r;
        initRow(&r);
        getRow(0, &r);
        os << "rowcount = " << getRowCount() << endl;
        os << "base rid = " << getBaseRid() << endl;
        os << "status = " << getStatus() << endl;
        os << "dbroot = " << getDBRoot() << endl;
        os << "row data...\n";

        for (uint32_t i = 0; i < getRowCount(); i++)
        {
            os << r.toString() << endl;
            r.nextRow();
        }
    }

    return os.str();
}

boost::shared_array<int> makeMapping(const RowGroup& r1, const RowGroup& r2)
{
    shared_array<int> ret(new int[r1.getColumnCount()]);
    //bool reserved[r2.getColumnCount()];
    bool* reserved = (bool*)alloca(r2.getColumnCount() * sizeof(bool));
    uint32_t i, j;

    for (i = 0; i < r2.getColumnCount(); i++)
        reserved[i] = false;

    for (i = 0; i < r1.getColumnCount(); i++)
    {
        for (j = 0; j < r2.getColumnCount(); j++)
            if ((r1.getKeys()[i] == r2.getKeys()[j]) && !reserved[j])
            {
                ret[i] = j;
                reserved[j] = true;
                break;
            }

        if (j == r2.getColumnCount())
            ret[i] = -1;
    }

    return ret;
}

void applyMapping(const boost::shared_array<int>& mapping, const Row& in, Row* out)
{
    applyMapping(mapping.get(), in, out);
}

void applyMapping(const std::vector<int>& mapping, const Row& in, Row* out)
{
    applyMapping((int*) &mapping[0], in, out);
}

void applyMapping(const int* mapping, const Row& in, Row* out)
{
    uint32_t i;

    for (i = 0; i < in.getColumnCount(); i++)
        if (mapping[i] != -1)
        {
            if (UNLIKELY(in.getColTypes()[i] == execplan::CalpontSystemCatalog::VARBINARY ||
                         in.getColTypes()[i] == execplan::CalpontSystemCatalog::BLOB ||
                         in.getColTypes()[i] == execplan::CalpontSystemCatalog::TEXT))
                out->setVarBinaryField(in.getVarBinaryField(i), in.getVarBinaryLength(i), mapping[i]);
            else if (UNLIKELY(in.isLongString(i)))
                out->setStringField(in.getStringPointer(i), in.getStringLength(i), mapping[i]);
            //out->setStringField(in.getStringField(i), mapping[i]);
            else if (UNLIKELY(in.isShortString(i)))
                out->setUintField(in.getUintField(i), mapping[i]);
            else if (UNLIKELY(in.getColTypes()[i] == execplan::CalpontSystemCatalog::LONGDOUBLE))
                out->setLongDoubleField(in.getLongDoubleField(i), mapping[i]);
            else if (in.isUnsigned(i))
                out->setUintField(in.getUintField(i), mapping[i]);
            else
                out->setIntField(in.getIntField(i), mapping[i]);
        }
}

RowGroup& RowGroup::operator+=(const RowGroup& rhs)
{
    boost::shared_array<bool> tmp;
    uint32_t i, j;
    //not appendable if data is set
    assert(!data);

    tmp.reset(new bool[columnCount + rhs.columnCount]);

    for (i = 0; i < columnCount; i++)
        tmp[i] = forceInline[i];

    for (j = 0; j < rhs.columnCount; i++, j++)
        tmp[i] = rhs.forceInline[j];

    forceInline.swap(tmp);

    columnCount += rhs.columnCount;
    oids.insert(oids.end(), rhs.oids.begin(), rhs.oids.end());
    keys.insert(keys.end(), rhs.keys.begin(), rhs.keys.end());
    types.insert(types.end(), rhs.types.begin(), rhs.types.end());
    scale.insert(scale.end(), rhs.scale.begin(), rhs.scale.end());
    precision.insert(precision.end(), rhs.precision.begin(), rhs.precision.end());
    colWidths.insert(colWidths.end(), rhs.colWidths.begin(), rhs.colWidths.end());

    //    +4  +4  +8       +2 +4  +8
    // (2, 6, 10, 18) + (2, 4, 8, 16) = (2, 6, 10, 18, 20, 24, 32)
    for (i = 1; i < rhs.stOffsets.size(); i++)
    {
        stOffsets.push_back(stOffsets.back() + rhs.stOffsets[i] - rhs.stOffsets[i - 1]);
        oldOffsets.push_back(oldOffsets.back() + rhs.oldOffsets[i] - rhs.oldOffsets[i - 1]);
    }

    hasLongStringField = rhs.hasLongStringField || hasLongStringField;
    offsets = (useStringTable ? &stOffsets[0] : &oldOffsets[0]);

    return *this;
}

RowGroup operator+(const RowGroup& lhs, const RowGroup& rhs)
{
    RowGroup temp(lhs);
    return temp += rhs;
}

uint32_t RowGroup::getDBRoot() const
{
    return *((uint32_t*) &data[dbRootOffset]);
}

void RowGroup::addToSysDataList(execplan::CalpontSystemCatalog::NJLSysDataList& sysDataList)
{
    execplan::ColumnResult* cr;

    rowgroup::Row row;
    initRow(&row);
    uint32_t rowCount = getRowCount();
    uint32_t columnCount = getColumnCount();

    for (uint32_t i = 0; i < rowCount; i++)
    {
        getRow(i, &row);

        for (uint32_t j = 0; j < columnCount; j++)
        {
            int idx = sysDataList.findColumn(getOIDs()[j]);

            if (idx >= 0)
            {
                cr = sysDataList.sysDataVec[idx];
            }
            else
            {
                cr = new execplan::ColumnResult();
                cr->SetColumnOID(getOIDs()[j]);
                sysDataList.push_back(cr);
            }

            // @todo more data type checking. for now only check string, midint and bigint
            switch ((getColTypes()[j]))
            {
                case CalpontSystemCatalog::CHAR:
                case CalpontSystemCatalog::VARCHAR:
                {
                    switch (getColumnWidth(j))
                    {
                        case 1:
                            cr->PutData(row.getUintField<1>(j));
                            break;

                        case 2:
                            cr->PutData(row.getUintField<2>(j));
                            break;

                        case 4:
                            cr->PutData(row.getUintField<4>(j));
                            break;

                        case 8:
                            cr->PutData(row.getUintField<8>(j));
                            break;

                        default:
                        {
                            string s = row.getStringField(j);
                            cr->PutStringData(string(s.c_str(), strlen(s.c_str())));
                        }
                    }

                    break;
                }

                case CalpontSystemCatalog::MEDINT:
                case CalpontSystemCatalog::INT:
                case CalpontSystemCatalog::UINT:
                    cr->PutData(row.getIntField<4>(j));
                    break;

                case CalpontSystemCatalog::DATE:
                    cr->PutData(row.getUintField<4>(j));
                    break;

                default:
                    cr->PutData(row.getIntField<8>(j));
            }

            cr->PutRid(row.getFileRelativeRid());
        }
    }
}

void RowGroup::setDBRoot(uint32_t dbroot)
{
    *((uint32_t*) &data[dbRootOffset]) = dbroot;
}

RGData RowGroup::duplicate()
{
    RGData ret(*this, getRowCount());

    if (useStringTable)
    {
        // this isn't a straight memcpy of everything b/c it might be remapping strings.
        // think about a big memcpy + a remap operation; might be faster.
        Row r1, r2;
        RowGroup rg(*this);
        rg.setData(&ret);
        rg.resetRowGroup(getBaseRid());
        rg.setStatus(getStatus());
        rg.setRowCount(getRowCount());
        rg.setDBRoot(getDBRoot());
        initRow(&r1);
        initRow(&r2);
        getRow(0, &r1);
        rg.getRow(0, &r2);

        for (uint32_t i = 0; i < getRowCount(); i++)
        {
            copyRow(r1, &r2);
            r1.nextRow();
            r2.nextRow();
        }
    }
    else
        memcpy(ret.rowData.get(), data, getDataSize());

    return ret;
}


void Row::setStringField(const std::string& val, uint32_t colIndex)
{
    uint64_t offset;
    uint64_t length;

    //length = strlen(val.c_str()) + 1;
    length = val.length();

    if (length > getColumnWidth(colIndex))
        length = getColumnWidth(colIndex);

    if (inStringTable(colIndex))
    {
        offset = strings->storeString((const uint8_t*) val.data(), length);
        *((uint64_t*) &data[offsets[colIndex]]) = offset;
//		cout << " -- stored offset " << *((uint32_t *) &data[offsets[colIndex]])
//				<< " length " << *((uint32_t *) &data[offsets[colIndex] + 4])
//				<< endl;
    }
    else
    {
        memcpy(&data[offsets[colIndex]], val.data(), length);
        memset(&data[offsets[colIndex] + length], 0,
               offsets[colIndex + 1] - (offsets[colIndex] + length));
    }
}

void RowGroup::append(RGData& rgd)
{
    RowGroup tmp(*this);
    Row src, dest;

    tmp.setData(&rgd);
    initRow(&src);
    initRow(&dest);
    tmp.getRow(0, &src);
    getRow(getRowCount(), &dest);

    for (uint32_t i = 0; i < tmp.getRowCount(); i++, src.nextRow(), dest.nextRow())
    {
        //cerr << "appending row: " << src.toString() << endl;
        copyRow(src, &dest);
    }

    setRowCount(getRowCount() + tmp.getRowCount());
}

void RowGroup::append(RowGroup& rg)
{
    append(*rg.getRGData());
}

void RowGroup::append(RGData& rgd, uint32_t startPos)
{
    RowGroup tmp(*this);
    Row src, dest;

    tmp.setData(&rgd);
    initRow(&src);
    initRow(&dest);
    tmp.getRow(0, &src);
    getRow(startPos, &dest);

    for (uint32_t i = 0; i < tmp.getRowCount(); i++, src.nextRow(), dest.nextRow())
    {
        //cerr << "appending row: " << src.toString() << endl;
        copyRow(src, &dest);
    }

    setRowCount(getRowCount() + tmp.getRowCount());
}

void RowGroup::append(RowGroup& rg, uint32_t startPos)
{
    append(*rg.getRGData(), startPos);
}

RowGroup RowGroup::truncate(uint32_t cols)
{
    idbassert(cols <= columnCount);

    RowGroup ret(*this);
    ret.columnCount = cols;
    ret.oldOffsets.resize(cols + 1);
    ret.stOffsets.resize(cols + 1);
    ret.colWidths.resize(cols);
    ret.oids.resize(cols);
    ret.keys.resize(cols);
    ret.types.resize(cols);
    ret.scale.resize(cols);
    ret.precision.resize(cols);
    ret.forceInline.reset(new bool[cols]);
    memcpy(ret.forceInline.get(), forceInline.get(), cols * sizeof(bool));

    ret.hasLongStringField = false;

    for (uint32_t i = 0; i < columnCount; i++)
    {
        if (colWidths[i] >= sTableThreshold && !forceInline[i])
        {
            ret.hasLongStringField = true;
            break;
        }
    }

    ret.useStringTable = (ret.useStringTable && ret.hasLongStringField);
    ret.offsets = (ret.useStringTable ? &ret.stOffsets[0] : &ret.oldOffsets[0]);
    return ret;
}

}

// vim:ts=4 sw=4:

